Software APIs
dt_edn.h
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1// Copyright lowRISC contributors (OpenTitan project).
2// Licensed under the Apache License, Version 2.0, see LICENSE for details.
3// SPDX-License-Identifier: Apache-2.0
4//
5// Device table API auto-generated by `dtgen`
6
7#ifndef OPENTITAN_DT_EDN_H_
8#define OPENTITAN_DT_EDN_H_
9
10#ifdef __cplusplus
11extern "C" {
12#endif // __cplusplus
13
14/**
15 * @file
16 * @brief Device Tables (DT) for IP edn and top darjeeling.
17 *
18 * This file contains the type definitions and global functions of the edn.
19 */
20
21#include "hw/top/dt/dt_api.h"
22#include <stdint.h>
23
24
25
26/**
27 * List of instances.
28 */
29typedef enum dt_edn {
30 kDtEdn0 = 0, /**< edn0 */
31 kDtEdn1 = 1, /**< edn1 */
32 kDtEdnFirst = 0, /**< \internal First instance */
33 kDtEdnCount = 2, /**< \internal Number of instances */
34} dt_edn_t;
35
36/**
37 * List of register blocks.
38 *
39 * Register blocks are guaranteed to start at 0 and to be consecutively numbered.
40 */
41typedef enum dt_edn_reg_block {
42 kDtEdnRegBlockCore = 0, /**< */
43 kDtEdnRegBlockCount = 1, /**< \internal Number of register blocks */
44} dt_edn_reg_block_t;
45
46/** Primary register block (associated with the "primary" set of registers that control the IP). */
47static const dt_edn_reg_block_t kDtEdnRegBlockPrimary = kDtEdnRegBlockCore;
48
49/**
50 * List of memories.
51 *
52 * Memories are guaranteed to start at 0 and to be consecutively numbered.
53 */
54typedef enum dt_edn_memory {
55 kDtEdnMemoryCount = 0, /**< \internal Number of memories */
56} dt_edn_memory_t;
57
58/**
59 * List of IRQs.
60 *
61 * IRQs are guaranteed to be numbered consecutively from 0.
62 */
63typedef enum dt_edn_irq {
64 kDtEdnIrqEdnCmdReqDone = 0, /**< Asserted when a software CSRNG request has completed. */
65 kDtEdnIrqEdnFatalErr = 1, /**< Asserted when a FIFO error occurs. */
66 kDtEdnIrqCount = 2, /**< \internal Number of IRQs */
67} dt_edn_irq_t;
68
69/**
70 * List of Alerts.
71 *
72 * Alerts are guaranteed to be numbered consecutively from 0.
73 */
74typedef enum dt_edn_alert {
75 kDtEdnAlertRecovAlert = 0, /**< This alert is triggered when entropy bus data matches on consecutive clock cycles. */
76 kDtEdnAlertFatalAlert = 1, /**< This alert triggers (i) if an illegal state machine state is reached, or
77(ii) if a fatal integrity failure is detected on the TL-UL bus. */
78 kDtEdnAlertCount = 2, /**< \internal Number of Alerts */
79} dt_edn_alert_t;
80
81/**
82 * List of clock ports.
83 *
84 * Clock ports are guaranteed to be numbered consecutively from 0.
85 */
86typedef enum dt_edn_clock {
87 kDtEdnClockClk = 0, /**< Clock port clk_i */
88 kDtEdnClockCount = 1, /**< \internal Number of clock ports */
89} dt_edn_clock_t;
90
91/**
92 * List of reset ports.
93 *
94 * Reset ports are guaranteed to be numbered consecutively from 0.
95 */
96typedef enum dt_edn_reset {
97 kDtEdnResetRst = 0, /**< Reset port rst_ni */
98 kDtEdnResetCount = 1, /**< \internal Number of reset ports */
99} dt_edn_reset_t;
100
101/**
102 * List of supported hardware features.
103 */
104#define OPENTITAN_EDN_HAS_MODE_BOOT 1
105#define OPENTITAN_EDN_HAS_MODE_AUTO 1
106#define OPENTITAN_EDN_HAS_MODE_SW 1
107#define OPENTITAN_EDN_HAS_TRACK_SEED_COMPLIANCE 1
108#define OPENTITAN_EDN_HAS_BUS_CMP_ALERT 1
109
110
111
112/**
113 * Get the edn instance from an instance ID
114 *
115 * For example, `dt_uart_from_instance_id(kDtInstanceIdUart3) == kDtUart3`.
116 *
117 * @param inst_id Instance ID.
118 * @return A edn instance.
119 *
120 * **Note:** This function only makes sense if the instance ID has device type edn,
121 * otherwise the returned value is unspecified.
122 */
123dt_edn_t dt_edn_from_instance_id(dt_instance_id_t inst_id);
124
125/**
126 * Get the instance ID of an instance.
127 *
128 * @param dt Instance of edn.
129 * @return The instance ID of that instance.
130 */
131dt_instance_id_t dt_edn_instance_id(dt_edn_t dt);
132
133/**
134 * Get the register base address of an instance.
135 *
136 * @param dt Instance of edn.
137 * @param reg_block The register block requested.
138 * @return The register base address of the requested block.
139 */
140uint32_t dt_edn_reg_block(
141 dt_edn_t dt,
142 dt_edn_reg_block_t reg_block);
143
144/**
145 * Get the primary register base address of an instance.
146 *
147 * This is just a convenience function, equivalent to
148 * `dt_edn_reg_block(dt, kDtEdnRegBlockCore)`
149 *
150 * @param dt Instance of edn.
151 * @return The register base address of the primary register block.
152 */
153static inline uint32_t dt_edn_primary_reg_block(
154 dt_edn_t dt) {
155 return dt_edn_reg_block(dt, kDtEdnRegBlockCore);
156}
157
158/**
159 * Get the base address of a memory.
160 *
161 * @param dt Instance of edn.
162 * @param mem The memory requested.
163 * @return The base address of the requested memory.
164 */
165uint32_t dt_edn_memory_base(
166 dt_edn_t dt,
167 dt_edn_memory_t mem);
168
169/**
170 * Get the size of a memory.
171 *
172 * @param dt Instance of edn.
173 * @param mem The memory requested.
174 * @return The size of the requested memory.
175 */
176uint32_t dt_edn_memory_size(
177 dt_edn_t dt,
178 dt_edn_memory_t mem);
179
180/**
181 * Get the PLIC ID of a edn IRQ for a given instance.
182 *
183 * If the instance is not connected to the PLIC, this function
184 * will return `kDtPlicIrqIdNone`.
185 *
186 * @param dt Instance of edn.
187 * @param irq A edn IRQ.
188 * @return The PLIC ID of the IRQ of this instance.
189 */
190dt_plic_irq_id_t dt_edn_irq_to_plic_id(
191 dt_edn_t dt,
192 dt_edn_irq_t irq);
193
194/**
195 * Convert a global IRQ ID to a local edn IRQ type.
196 *
197 * @param dt Instance of edn.
198 * @param irq A PLIC ID that belongs to this instance.
199 * @return The edn IRQ, or `kDtEdnIrqCount`.
200 *
201 * **Note:** This function assumes that the PLIC ID belongs to the instance
202 * of edn passed in parameter. In other words, it must be the case that
203 * `dt_edn_instance_id(dt) == dt_plic_id_to_instance_id(irq)`. Otherwise, this function
204 * will return `kDtEdnIrqCount`.
205 */
206dt_edn_irq_t dt_edn_irq_from_plic_id(
207 dt_edn_t dt,
208 dt_plic_irq_id_t irq);
209
210
211/**
212 * Get the alert ID of a edn alert for a given instance.
213 *
214 * **Note:** This function only makes sense if the instance is connected to the Alert Handler. For any
215 * instances where the instance is not connected, the return value is unspecified.
216 *
217 * @param dt Instance of edn.
218 * @param alert A edn alert.
219 * @return The Alert Handler alert ID of the alert of this instance.
220 */
221dt_alert_id_t dt_edn_alert_to_alert_id(
222 dt_edn_t dt,
223 dt_edn_alert_t alert);
224
225/**
226 * Convert a global alert ID to a local edn alert type.
227 *
228 * @param dt Instance of edn.
229 * @param alert A global alert ID that belongs to this instance.
230 * @return The edn alert, or `kDtEdnAlertCount`.
231 *
232 * **Note:** This function assumes that the global alert ID belongs to the
233 * instance of edn passed in parameter. In other words, it must be the case
234 * that `dt_edn_instance_id(dt) == dt_alert_id_to_instance_id(alert)`. Otherwise,
235 * this function will return `kDtEdnAlertCount`.
236 */
237dt_edn_alert_t dt_edn_alert_from_alert_id(
238 dt_edn_t dt,
239 dt_alert_id_t alert);
240
241
242
243/**
244 * Get the clock signal connected to a clock port of an instance.
245 *
246 * @param dt Instance of edn.
247 * @param clk Clock port.
248 * @return Clock signal.
249 */
250dt_clock_t dt_edn_clock(
251 dt_edn_t dt,
252 dt_edn_clock_t clk);
253
254/**
255 * Get the reset signal connected to a reset port of an instance.
256 *
257 * @param dt Instance of edn.
258 * @param rst Reset port.
259 * @return Reset signal.
260 */
261dt_reset_t dt_edn_reset(
262 dt_edn_t dt,
263 dt_edn_reset_t rst);
264
265
266
267#ifdef __cplusplus
268} // extern "C"
269#endif // __cplusplus
270
271#endif // OPENTITAN_DT_EDN_H_